Systems and methods for thermoforming dental aligners

ABSTRACT

A system includes a plurality of assemblies each configured to support a dental mold and a material, a heating system configured to heat the material, a forming system configured to form a chamber encompassing the dental mold and at least a portion of the heated material, and to cause the heated material to form over the dental mold, and a conveyor system configured to move the plurality of assemblies from a loading area to the heating system, from the heating system to the forming system, and from the forming system to an unloading area.

CROSS REFERENCE TO RELATED PATENT APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/425,526, filed May 29, 2019, which is a continuation of U.S. patentapplication Ser. No. 16/188,570, filed Nov. 13, 2018, each of which arehereby incorporated by reference in their entirety.

BACKGROUND

The present disclosure relates generally to dental aligners. Morespecifically, the present disclosure relates to thermoforming dentalaligners.

Dental aligners for positioning teeth can be thermoformed over positivemolds of a person's teeth that depict a repositioned state of theperson's teeth. Such a thermoforming process typically involves heatinga material and then pressure molding the material onto the positivemold. However, traditional processes for thermoforming dental alignersare usually labor intensive and require a person to manually manipulatepositive molds and materials throughout the thermoforming process. Forexample, some thermoforming processes may require a technician to inserta positive mold including thermoforming material into a heating chamberto heat the thermoforming material, and then to move the positive moldand thermoforming material to a forming chamber to thermoform thethermoforming material to the positive mold.

Positive molds for the thermoforming process can be created from anegative dental impression or a digital scan of the person's teeth. Forexample, to take a dental impression, a dental tray having a viscous,thixotropic impression material therein is fit over the dental arches ofthe person, and the impression material sets to a solid thereby leavingan imprint of the structures in the person's mouth. When removed fromthe mouth, the impression provides a detailed and stable negative of theperson's teeth. Such a process has traditionally been performed in adental office under the supervision of a dental professional, andtherefore requires significant time and inconvenience. Furthercomplicating the process, the dental office delivers the impressions toan outside vendor for manufacturing dental aligners, which can result inthe person having to revisit the dental office to retake impressions ordigital scans if any errors are discovered, such as an incomplete orinaccurate impression of the person's teeth and tissues.

SUMMARY

An embodiment relates to a system including a plurality of thermoformingassemblies, a heating system, a forming system, and a conveyor system.The plurality of thermoforming assemblies are each configured to supporta dental mold and a thermoforming material. The heating system includesa first heater, a second heater, and a temperature sensor. The firstheater is configured to heat the thermoforming material when thethermoforming material is proximate the first heater. The second heateris configured to heat the thermoforming material when the thermoformingmaterial is proximate the second heater. The temperature sensor isarranged to detect a temperature of the thermoforming material when thethermoforming material is proximate either of the first heater and thesecond heater. The forming system includes an actuator and a pressuresystem. The actuator is configured to form a chamber encompassing thedental mold and a portion of the heated thermoforming material. Thepressure system is configured to pressurize the chamber to compress theheated thermoforming material to the dental mold. The conveyor system isconfigured to move the plurality of thermoforming assemblies in astepwise movement sequence from a loading area to the heating system,then from the heating system to the forming system, and then from theforming system to an unloading area. Each stepwise movement of thethermoforming assemblies is based on a temperature of a firstthermoforming material of a first thermoforming assembly at the firstheater and a temperature of a second thermoforming material of a secondthermoforming assembly at the second heater.

Another embodiment relates to a system including a controller configuredto control a conveyor system to move a thermoforming assembly in astepwise movement sequence. The thermoforming assembly includes a dentalmold and a thermoforming material. The stepwise movement sequenceincludes moving the assembly in sequence to a first predeterminedposition proximate a first heater, then to a second predeterminedposition proximate a second heater, then to a third predeterminedposition proximate a forming system. The thermoforming assembly remainsat each predetermined position for a predetermined time. The controlleris further configured to control the first heater to heat thethermoforming material above a first temperature threshold or within afirst temperature range, control the second heater to heat thethermoforming material above a second temperature threshold or within asecond temperature range, and control the forming system to compress theheated thermoforming material to the dental mold to form a shape of adental aligner based on the thermoforming material being above a formingtemperature threshold or within a forming temperature range.

Another embodiment relates to a method including determining, based ondata from a temperature sensor configured to detect a temperature of athermoforming material at a first heater of a heating system, that thetemperature of the thermoforming material meets a first temperaturerequirement while a thermoforming assembly including the thermoformingmaterial and a dental mold is located at the first heater. The methodfurther includes controlling a conveyor system coupled with thethermoforming assembly to advance the thermoforming assembly from thefirst heater to a second heater of the heating system. The methodfurther includes determining, based on data from the temperature sensor,that the temperature of the thermoforming material meets a secondtemperature requirement while the thermoforming assembly is located atthe second heater. The method further includes controlling the conveyorsystem to advance the thermoforming assembly from the second heater to aforming system. The method further includes controlling a forming systemincluding an actuator and a pressure system to apply pressure to anupper portion of a chamber around the dental mold and at least a portionof the thermoforming material to compress the thermoforming material tothe dental mold.

Another embodiment relates to a system including a first thermoformingsystem, a second thermoforming system, and a third thermoforming system.The first thermoforming system includes a first heating system and afirst forming system. The first heating system is configured to heat afirst thermoforming material above a first temperature threshold orwithin a first temperature range. The first forming system is configuredto compress the first thermoforming material to a dental mold to form afirst dental aligner having a first hardness or first thickness. Thesecond thermoforming system includes a second heating system and asecond forming system. The second heating system is configured to heat asecond thermoforming material above a second temperature threshold orwithin a second temperature range. The second forming system isconfigured to compress the second thermoforming material to the dentalmold to form a second dental aligner having a second hardness or secondthickness. The third thermoforming system includes a third heatingsystem and a third forming system. The third heating system isconfigured to heat a third thermoforming material above a thirdtemperature threshold or within a third temperature range. The thirdforming system is configured to compress the third thermoformingmaterial to the dental mold to form a third dental aligner having athird hardness or third thickness.

This summary is illustrative only and is not intended to be in any waylimiting. Other aspects, inventive features, and advantages of thedevices or processes described herein will become apparent in thedetailed description set forth herein, taken in conjunction with theaccompanying figures, wherein like reference numerals refer to likeelements.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration of a system for thermoforming dental alignersincluding a first motorized belt and a second motorized belt, accordingto an exemplary embodiment.

FIG. 2 is a top plan view of the system for thermoforming dentalaligners of FIG. 1, according to an exemplary embodiment.

FIG. 3 is an isolated view of the first motorized belt of the system ofFIG. 1, according to an exemplary embodiment.

FIG. 4 is an illustration of a thermoforming assembly of the system ofFIG. 1, according to an exemplary embodiment.

FIG. 5 is an illustration of a first transfer device for transferringthe thermoforming assembly of FIG. 4 from the first motorized belt tothe second motorized belt of FIG. 3, shown in a pre-transfer position,according to an exemplary embodiment.

FIG. 6 is an illustration of the first transfer device of FIG. 5 shownin a post-transfer position, according to an exemplary embodiment.

FIG. 7 is an illustration of a second transfer device for transferringthe thermoforming assembly of FIG. 4 from the second motorized belt ofFIG. 3 to the first motorized belt, shown in a pre-transfer position,according to an exemplary embodiment.

FIG. 8 is an illustration of the second transfer device of FIG. 7 shownin a post-transfer position, according to an exemplary embodiment.

FIG. 9 is a perspective view of a heating station of the system of FIG.1, according to an exemplary embodiment.

FIG. 10 is a flowchart of an example method of thermoforming dentalaligners, according to an exemplary embodiment.

DETAILED DESCRIPTION

Before turning to the figures, which illustrate certain exemplaryembodiments in detail, it should be understood that the presentdisclosure is not limited to the details or methodology set forth in thedescription or illustrated in the figures. It should also be understoodthat the terminology used herein is for the purpose of description onlyand should not be regarded as limiting.

Referring generally to the figures, described herein are systems andmethods for thermoforming dental aligners. A motorized belt is rotatablebetween a first belt-transfer device, a heating station, a formingstation, and a second belt-transfer device. The belt includes cleatsthat may form a bay for receiving a thermoforming assembly. The heatingstation includes a plurality of heaters including a first heater and asecond heater. A temperature sensor is arranged to detect a temperatureof thermoforming material located proximate a dental mold located on thethermoforming assembly. The thermoforming assembly with thethermoforming material is moved from the first heater to the secondheater after the temperature of the thermoforming material meets a firstthreshold, and from the second heater to the forming station after thetemperature of the thermoforming material meets a second threshold. Anactuator and a pressure assembly are controlled to apply pressure to anupper portion of a chamber around the heated thermoforming material andthe dental mold to compress the thermoforming material to the dentalmold.

The embodiments described herein provide for automated or semi-automatedmanufacturing of dental aligners. While the systems and methodsdisclosed herein specifically relate to or reference the fabrication ofdental aligners, it will be appreciated that the systems and methodsdisclosed herein could also be used to create retainers, night guards,or other dental devices by thermoforming materials over a dental mold.The embodiments disclosed herein may increase the consistency andproduction of dental aligners. Furthermore, such embodiments maydecrease the likelihood of human error. For instance, in the embodimentsdescribed herein, operator intervention and input is minimized, thuslessening operator exposure and any resulting human error. It will alsobe appreciated that operator intervention can be even further minimizedas operator actions can be further automated. The embodiments describedherein may rapidly output dental aligners as compared to manuallygenerating dental aligners on an individual basis. Various otheradvantages may become apparent based on the following description.

Referring now to FIG. 1-FIG. 3, an embodiment of a system 100 forthermoforming dental aligners is shown. Specifically, FIG. 1 and FIG. 2are illustrations of the overall system 100 for thermoforming dentalaligners, and FIG. 3 is an illustration of an isolated view of a firstmotorized belt 102 of the system 100, according to an exemplaryembodiment. The system 100 is shown to include a first motorized belt102 configured to rotate in a first direction A. The system is alsoshown to include a second motorized belt 114 configured to rotate in asecond direction B. In some embodiments, the first direction A andsecond direction B may be parallel and opposite to one another. Thefirst motorized belt 102 may also be referred to herein as athermoforming belt, and the second motorized belt 114 may also bereferred to as a loading belt.

The first motorized belt 102 may include a plurality of cleats 104 whichextend perpendicular with respect to the first direction A on the firstmotorized belt 102. The cleats 104 form a bay 106 for receiving athermoforming assembly 108. The first motorized belt 102 is configuredto rotate between a heating station 110 and a forming station 112. Thefirst motorized belt 102 is driven by a motor 120. For instance, thefirst motorized belt 102 generally includes a pulley system including afirst pulley 300 and a second pulley 302. The first pulley 300 is drivenby the motor 120 (as shown in FIG. 3) via a shaft 304 extending betweenand coupling the motor 120 to the pulley 300. The first motorized belt102 is shown to include a supporting frame structure 306 to maintain therigidity of the first motorized belt 102. As the motor 120 drives thepulley 300, the first motorized belt 102 rotates (e.g., with the firstpulley 300), which in turn causes rotation of the second pulley 302.While only the first motorized belt 102 is shown in FIG. 3, it will beappreciated that the second motorized belt 114 can be similarlyconstructed and operated as the first motorized belt 102. For example,the second motorized belt 114 can be driven separate from the firstmotorized belt 102 or be driven by the same motor 120 of the firstmotorized belt 102. In some embodiments, the first motorized belt 102can drive the second motorized belt 114, or the second motorized belt114 can drive the first motorized belt 102.

The thermoforming assembly 108 is assembled (e.g., as shown in FIG. 4)by an operator, for instance, and positioned on the belt system,comprising the first motorized belt 102 and the second motorized below114 (e.g., between the cleats 104). In some embodiments, thethermoforming assembly 108 is not removed from the belt system by theoperator. Rather, only the thermoforming material 414 and the mold 406are removed and added to the thermoforming assembly 108 as part of thethermoforming process (e.g., the thermoforming assembly 108 is securedor removably secured in place via the cleats 104).

As described in greater detail below, the thermoforming assembly 108 isconfigured to support, retain, hold, or otherwise carry thermoformingmaterial 414 and a dental mold 406. The first motorized belt 102 carriesthe thermoforming assembly 108 (including the thermoforming material 414and dental mold 406) to the heating station 110 and the forming station112. The thermoforming material 414 is heated at the heating station110. An upper chamber structure 134 at the forming station 112 engageswith a dental mold nest 404 of the thermoforming assembly 108 to form achamber. The upper chamber structure 134 downwardly towards the dentalmold nest 404, which is lifted up towards the thermoforming material 414by a lifting device 136. The upper chamber structure 134 and dental moldnest 404 sandwich the thermoforming material 414 to form a seal (thuseliminating the need for any other sealing structure such as an O-ring).Air is removed from the chamber or applied (e.g., by a pressure systemthat includes a vacuum) inside the chamber structure 134 which causesthe thermoforming material 414 to form onto the mold. When thethermoforming material 414 is thermoformed to the dental mold 406, thethermoforming material 414 may be used as a dental aligner by a user forrepositioning the user's teeth. For instance, the thermoformedthermoforming materials (e.g., referred to hereinafter as the dentalaligners) are trimmed for comfort, sent to the user, and positioned bythe user in the user's mouth for repositioning the user's teeth.

Referring now to FIG. 1 and FIG. 4, the thermoforming assembly 108 mayinclude various components and elements for thermoforming thermoformingmaterial 414 to a dental mold 406. Specifically, FIG. 4 depicts anembodiment of a thermoforming assembly 108 of the system 100, accordingto an exemplary embodiment. The thermoforming assembly 108 includes asupporting surface 400. The supporting surface 400 includes notches 402configured to slide between the cleats 104. For instance, the cleats 104can include lips 800 (of FIG. 8) sized to extend over the notches 402.The supporting surface 400 may slide between the cleats 104 with thenotches 402 engaging the lips 800 of the cleats 104.

The supporting surface 400 is shown to include a dental mold nest 404.The dental mold nest 404 is configured to receive a dental mold 406(e.g., a mold of an impression, model, or other three-dimensionalrepresentation of a person's dental arch). The dental mold nest 404 istooled, designed, or configured to receive the dental mold 406. As oneexample, the dental mold nest 404 may include a tooled portionconfigured to receive and secure the dental mold 405. The dental moldnest 404 is inserted into and rests upon the supporting surface 400. Forinstance, the supporting surface 400 is shown to include an opening 408.The dental mold nest 404 rests within the opening 408. The opening 408is shown to include features 410 (e.g., ledges, notches, etc.) along theinterior surface of the opening 408 which engage with features 412 on anexterior surface of the mold nest 304 (e.g., corresponding ledges,extensions, etc.). The dental mold nest 404 is positioned within theopening 408 such that the dental mold 406 is positioned upwardly on thethermoforming assembly 108.

The thermoforming assembly 108 may also include thermoforming material414. The thermoforming material 414 may be any type of material capableof being thermoformed, such as a polymeric material (e.g., plastic)configured to be heated for changing a surface contour of the polymericmaterial. The thermoforming material 414 may be retained within athermoforming material nest 416 positioned above the dental mold nest404 (e.g., by separators 418). In some embodiments, the thermoformingmaterial nest 416 may include a recession or recessed portion which issized to receive the thermoforming material 414. The recessed portionmay prevent lateral movement of the thermoforming material 414 duringtransportation, heating, and thermoforming.

The thermoforming material 414 may be retained within the thermoformingmaterial nest 416 via a retaining ring 420. In some embodiments, theretaining ring 420 may be constructed of or include magnetic material,and the thermoforming material nest 416 may also be constructed of orinclude magnetic material. In some embodiments, the retaining ring 420may include a different type of locking mechanism, such as fasteners,pins, clips, etc. The retaining ring 420 may be coupled to thethermoforming material nest 416 to prevent or inhibit the thermoformingmaterial 414 moving within the thermoforming material nest 416. Wheremagnetic material is used, the magnetic material for the retaining ring420 may interact with the magnetic material in the thermoformingmaterial nest 416 to magnetically couple the retaining ring 220 to thethermoforming material nest 416. The thermoforming material 414 may besandwiched between the retaining ring 420 and thermoforming materialnest 416, thus locking, retaining, or otherwise maintaining the positionof the thermoforming material 414 in the thermoforming material nest416. While magnetic material is described in the above embodiments, inother embodiments, the thermoforming material 414 may be locked,retained, or otherwise be maintained in the thermoforming material nest416 in a number of different ways, such as with screws, clips, etc.

Referring back to FIG. 1 and FIG. 2, the thermoforming assemblies 108may be loaded by an operator. The thermoforming assemblies 108 may bemaintained in a clean, sterile environment (e.g., in a clean room) toeliminate, control, or otherwise inhibit or prevent dust, particulatesor other contamination which may affect the integrity of the dentalaligners. The operator may assemble the thermoforming assemblies 108(e.g., as shown in FIG. 4). The operator may assemble the thermoformingassemblies 108 on the second motorized belt 114 (e.g., the loadingbelt). As stated above, the second motorized belt 114 may rotatesubstantially parallel to (e.g., along the direction A) the firstmotorized belt 102 (e.g., the primary motorized belt), but in theopposite direction (e.g., in the direction B).

Referring now to FIG. 1 and FIGS. 5-8, in some embodiments, the system100 includes transfer devices 116, 118 for transferring loadedthermoforming assemblies 108 from the second motorized belt 114 to thefirst motorized belt 102, and for transferring thermoforming assemblies108 with thermoforming material 414 that has undergone thermoformingfrom the first motorized belt 102 to the second motorized belt 114,respectively. Specifically, a transfer device 116 is shown in FIG. 5-6for transferring loaded thermoforming assemblies 108 from the secondmotorized belt 114 to the first motorized belt 102. A transfer device118 is shown in FIG. 7-8 for transferring thermoforming assemblies 108with thermoforming material 414 that has undergone thermoforming fromthe first motorized belt 102 to the second motorized belt 114. In someembodiments, the transfer devices 116, 118 may have aspects similar toone another. The transfer devices 116, 118 engage a thermoformingassembly 108 when the thermoforming assembly 108 is positioned at theend of the first motorized belt 102 and second motorized belt 114 (e.g.,the positions shown in FIG. 5-6 and FIG. 7-8, respectively). Thetransfer devices 116, 118 slide the thermoforming assembly 108 betweenthe first motorized belt 102 and second motorized belt 114. As can bebest seen in FIG. 8, the notches 402 (shown in FIG. 3) of thethermoforming assembly 108 slide between the lips 800 of the cleats 104.The transfer devices 116, 118 slide the thermoforming assembly 108between the first motorized belt 102 and the second motorized belt 114such that the thermoforming assembly 108 is maintained between cleats104, or in transit between cleats 104 of the different motorized belts.In some embodiments, the thermoforming assembly 108 may generally not beremovable within the system 100. Hence, the first motorized belt 102,second motorized belt 114, and transfer devices 116, 118 generally causethe thermoforming assemblies 108 to rotate in a circle through thesystem 100. In this embodiment, the thermoforming assemblies 108 areloaded, unloaded, and re-loaded with dental molds 406, thermoformingmaterial 414, etc., without being transferred between different belts.

Referring back to FIG. 1, in some embodiments, the first motorized belt102 and the second motorized belt 114 may be rotated, driven, etc. bythe same motor 120 (e.g., an electric motor, engine, etc.). The firstmotorized belt 102 and the second motorized belt 114 may be driven bythe same motor 120 such that the belts 102, 114 are driven at the samespeed and advance in the same stages as one another. Hence, the motor120 may advance the belts 102, 114 step wise between various stations.In driving the belts 102, 114 at the same speed and in the same stages,thermoforming assemblies 108 may correspondingly be advanced together(e.g., in unison), thus eliminating or lessening the likelihood ofbottlenecks. In such an embodiment, the belts 102, 114 are notcontinuously driven such that the belts 102, 114 do not continuouslymove.

Referring now to FIG. 1 and FIG. 9, the heating station 110 may includea plurality of heaters including a first heater 122 and a second heater124. Specifically, FIG. 9 shows a perspective view of the heatingstation 110, according to an exemplary embodiment. While two heaters areshown and described herein, in various embodiments, the heating station110 may include more or fewer heaters. Accordingly, the presentdisclosure is not limited to two heaters, and may include or otherwiseincorporate any number of heaters. The heaters 122, 124 supply, provide,or otherwise output heat, such as inductive heat, convective heat, etc.The heaters 122, 124 heat the thermoforming material 414 when thethermoforming assembly 108 is positioned proximate (such as beneath) theheaters 122, 124. The thermoforming assemblies 108 advance to a positionunderneath the first heater 122 and pause for heating by the firstheater 122. Next, the thermoforming assemblies 108 advance from thefirst heater 122 to the second heater 124 and pause for heating by thesecond heater 124. Next, the thermoforming assemblies 108 advance fromthe second heater 124 to the forming station 112, as discussed ingreater detail below. As one thermoforming assembly 108 advances fromthe first heater 122 to the second heater 124, another thermoformingassembly 108 may advance to the position underneath the first heater122.

The heaters 122, 124 are shown to be suspended above the thermoformingassemblies 108, as can be best seen in FIG. 2. The heaters 122, 124supply heat to the thermoforming material 414. The heating station 110includes at least one temperature sensor 126. The temperature sensors126 are configured to detect the temperature of the thermoformingmaterial 414 as the thermoforming material 414 is heated by the heaters122, 124. In some embodiments, the temperature sensors 126 are surfacetemperature sensors configured to detect the temperature of the surfaceof an item (e.g., the thermoforming material 414, the dental mold 406).In some embodiments, the heating station 110 includes a singletemperature sensor 126 designed or configured to detect the temperatureof the thermoforming material 414 when the thermoforming material 414 isheated by the first heater 122 and subsequently heated by the secondheater 124 (and to simultaneously or stepwise detect the temperature ofadditional thermoforming material at the first heater 122 while thethermoforming material 414 is at the second heater 124). In someembodiments, the heating station 110 includes at least two dedicatedtemperature sensors 126 for detecting the temperature of thethermoforming material 414 at the first heater 122 and the second heater124, respectively.

In some embodiments, the heaters 122, 124 are independently controlledbased on data from the temperature sensors 126. For instance, theheaters 122, 124 may slow down the heating process (e.g., by decreasingthe level of heat output by a heater) as the temperature of thethermoforming material 414 approaches various thresholds, as describedin greater detail below. Thus, the heaters 122, 124 may regulate thetemperature of the thermoforming material 414.

The forming station 112 is shown to include an actuator 128 and atemperature sensor 126. The temperature sensor may be similar to or partof a same temperature sensor system as the temperature sensors 126described above with respect to the heating station 110. In someembodiments, the controller 132 verifies that the temperature of thethermoforming material 414 proximate the forming station 112 is above athreshold temperature or within a temperature range before controllingthe actuator 128 and the pressure system 138 to thermoform thethermoforming material 414 (e.g., a temperature substantially the sameas the second temperature threshold that the thermoforming material 414reaches at the first heater, less than the second temperaturethreshold). In some embodiments, if the temperature of the thermoformingmaterial 414 proximate the forming station 112 does not pass thetemperature verification, the thermoforming material 414 is notthermoformed and instead cycles back around the system 100 to bethermoformed on another pass through the forming station 112. In anotherembodiment, a technician can remove the non-thermoformed thermoformingmaterial 414 if the thermoforming material 414 is compromised (e.g.,overheated, sagging, deformed) and replace it with a new thermoformingmaterial 414 to be thermoformed on another pass through the formingstation 112.

The actuator 128 may be designed or configured to press together theheated thermoforming material 414 and the dental mold 406. The actuator128 may be a pneumatic actuator 128, hydraulic actuator 128, etc. Theactuator 128 may be configured to press together the heatedthermoforming material 414 and dental mold 406.

In some embodiments, the actuator 128 presses together the thermoformingmaterial 414 and dental mold 406 by lifting the dental mold 406 towardsthe thermoforming material 414. The actuator 128 is shown to include anupper chamber structure 134 and a lifting device 136. The upper chamberstructure 134 may be sized to substantially match the size of the dentalmold nest 404. Referring briefly to FIGS. 1-3 and 9, the lifting device136 lifts the dental mold 406 upwardly towards the thermoformingmaterial 414. The lifting device 136 extends through an opening 130 ofthe first motorized belt 102 in the bay 106 defined by the cleats 104.The opening 130 extends through the first motorized belt 102. Theopening 130 may be sized similar to a size of the opening 408 in thethermoforming assembly 108. The lifting device 136 extends through bothopenings 130, 408, and lifts the dental mold nest 404 (with the dentalmold 406 positioned therein) towards the thermoforming material 414.

As the lifting device 136 lifts the dental mold nest 404 towards thethermoforming material 414, the upper chamber structure 134 movesdownwardly towards the dental mold nest 404. The upper chamber structure134 and the dental mold nest 404 may have a similar shape and size suchthat the outer perimeter of the dental mold nest 404 is aligned with thelower perimeter of the upper chamber structure 134. The upper chamberstructure 134 and dental mold nest 404 may together sandwich thethermoforming material 414. As the upper chamber structure 134 anddental mold nest 404 sandwich the thermoforming material 414, the upperchamber structure 134 and dental mold nest 404 are pushed together suchthat small opposing forces are exerted on the thermoforming material 414to act as a seal between the upper chamber structure 134 and the dentalmold nest 404. A lower chamber structure of the forming station 112 canapply pressure to an upper portion of the inner chamber or vacuumsuction to the inner chamber (e.g., below the thermoforming material 414and the dental mold 406 to pull the thermoforming material 414 down ontothe dental mold 406.

In another embodiment, the upper chamber structure 134 may introducepressurized air into the inner chamber (e.g., above the thermoformingmaterial 414). For instance, the system 100 may include a pressuresystem 138 including reservoir 140 storing pressurized air, a hose 142connecting the reservoir to the inner chamber (e.g., through the upperchamber structure 134), and a valve 144 for regulating pressurized airflow into the inner chamber. The valve 144 is opened when the innerchamber is formed to introduce pressurized air (for instance 80 psi tomaintain a 50 psi pressure inside the inner chamber, though the pressuremay range from 30 PSI to 100+ PSI in some embodiments) above thethermoforming material 414. As the pressurized air is introduced in theinner chamber (which is effectively sealed by the thermoforming material414 at the juncture between the upper chamber structure 134 and dentalmold nest 414), the thermoforming material 414 (which is softened, or ina glassy state) forms onto the dental mold 406.

In all embodiments, the dental mold 406 and thermoforming material 414may thus have complementary surface contours (e.g., the thermoformingmaterial 414 may become a negative impression of the dental mold 406).

Following the thermoforming material 414 forming onto the dental mold406 within the inner chamber, the upper chamber structure 134 may belifted up (or the dental mold nest 404 may be lowered) to remove theseal and return the inner chamber to a neutral pressure (e.g.,atmospheric pressure). The thermoforming material 414 naturally cools,and the thermoforming assembly 108, including the thermoforming material414 now thermoformed to the dental mold 406, is moved from the formingstation 112. The thermoforming material 414 is thermoformed to thedental mold 406 in a duration corresponding to the duration for heatingthe thermoforming material 414 of subsequent thermoforming assemblies108 at the first heater 122 and the second heater 124. Hence, each stepin the thermoforming process may be controlled to take approximately thesame duration such that various steps may not cause a bottleneck. Eachthermoforming assembly 108 may advance within the thermoforming processtogether with other thermoforming assemblies 108 such that eachthermoforming assembly 108 is processed in stages (e.g., similar to anassembly line).

The system 100 may include a controller 132. The controller 132 may becommunicably coupled to the temperature sensor(s) 126, the motor 120powering the motorized belt(s) 102, 114, the actuator 128, the transferdevice(s) 116, 118, etc. The controller 132 may include a processor andmemory. The processor may be a general purpose or specific purposeprocessor, an application specific integrated circuit (ASIC), one ormore field programmable gate arrays (FPGAs), a group of processingcomponents, or other suitable processing components. The processor maybe configured to execute computer code or instructions stored in memoryor received from other computer readable media (e.g., CDROM, networkstorage, a remote server, etc.) to perform one or more of the processesdescribed herein. The memory may include one or more data storagedevices (e.g., memory units, memory devices, computer-readable storagemedia, etc.) configured to store data, computer code, executableinstructions, or other forms of computer-readable information. Thememory may include random access memory (RAM), read-only memory (ROM),hard drive storage, temporary storage, non-volatile memory, flashmemory, optical memory, or any other suitable memory for storingsoftware objects and/or computer instructions. The memory may includedatabase components, object code components, script components, or anyother type of information structure for supporting the variousactivities and information structures described in the presentdisclosure. The memory may be communicably connected to the processorand may include computer code for executing (e.g., by the processor,etc.) one or more of the processes described herein.

The controller 132 may be designed or implemented to perform variousfunctions. For instance, the controller 132 may receive data from thetemperature sensor(s) 126, which may be used as feedback for controllingthe motor 120 that powers/drives the motorized belt(s) 102, 114, theactuator 128, the transfer device(s) 116, 118, the heaters 122, 124, thepressure system 138, etc. The controller 132 may include variousinstructions, which may be stored on memory. Such instructions may beexecuted by the processor. Hence, the processor may execute instructionsstored on memory and perform various functions associated therewith.

The controller 132 may be configured to position a thermoformingassembly 108 at the first heater 122. For instance, the controller 132may control the motor 120 to advance a loaded thermoforming assembly 108towards the transfer device 116. The controller 132 may control thetransfer device 116 to push the loaded thermoforming assembly 108 fromthe second motorized belt 114 to the first motorized belt 102. Thecontroller 132 can control the motor 120 to advance the loadedthermoforming assembly 108 underneath the first heater 122. In eachinstance where the motor 120 causes a thermoforming assembly 108 toadvance, another thermoforming assembly/bay 108, 106 may advance withinthe system 100. Thus, the bays 106 moving in the system 100 may advancein unison such that, when one bay 106 advances, another bay 106 advances(e.g., in a stepwise or piecewise fashion).

In some embodiments, the controller 132 may activate the first heater122 when the thermoforming assembly 108 is located underneath the firstheater 122. In some embodiments, the first heater 122 may be maintainedin an active state (e.g., the first heater 122 may output heatthroughout the process). The first heater 122 heats the thermoformingmaterial 414 located beneath the first heater 122. The temperaturesensor 126 detects the temperature of the thermoforming material 414.The temperature sensor 126 generates data corresponding to thetemperature of the thermoforming material 414, which is communicated tothe controller 132. In some embodiments, the temperature sensor 126generates such data in real-time or near real-time. For example, acurrent temperature of the thermoforming material 414 is generated bythe temperature sensor 126 as the thermoforming material 414 is heated.

The controller 132 receives the data corresponding to the temperature ofthe thermoforming material 414. The controller 132 determines, based onthe data from the temperature sensor 126, whether the temperature of thethermoforming material 414 meets a first temperature threshold. “Meets,”as used herein with reference to a threshold, means satisfying athreshold (e.g., being the same as, falling within a range, exceeding aminimum, being less than a maximum, etc.). The first temperaturethreshold may be set by a dental aligner manufacturer/producer. Thefirst temperature threshold may be static, or the first temperaturethreshold may be dynamic (e.g., based on the type of thermoformingmaterial, the hardness of the thermoforming material, the thickness ofthe thermoforming material, etc.). The first temperature threshold maybe, for instance, a range of temperatures. As one example, the firsttemperature threshold may be 120° F.-300° F. The first temperaturethreshold may be a threshold used for advancing the thermoformingassembly 108 from the first heater 122 to the second heater 124. Whenthe controller 132 determines that the temperature of the thermoformingmaterial 414 meets the first threshold, the controller 132 controls themotor 120 to advance the thermoforming assembly 108 from the firstheater 122 to the second heater 124. When the controller 132 determinesthat the temperature of the thermoforming material 414 does not meet thefirst threshold (e.g., is less than the first threshold), the controller132 maintains the thermoforming assembly 108 at the first heater 122until the temperature of the thermoforming material 414 meets the firstthreshold.

The controller 132 advances the thermoforming assembly 108 from thefirst heater 122 to the second heater 124. In some embodiments, thesecond heater 124 may be similar to at least some aspects of the firstheater 122. However, in some embodiments, the first heater 122 isoperated differently than the second heater 124 (e.g., at a differenttemperature, for a different duration for each thermoforming assembly108, applying a different temperature pattern). The second heater 124similarly outputs heat to the thermoforming material 414. A temperaturesensor 126 (described herein as the temperature sensor 126 though, insome embodiments, may be a dedicated temperature sensor for the secondheater 124) detects a temperature of the thermoforming material 414while the thermoforming material 414 is heated by the second heater 124.The controller 132 receives the data corresponding to the temperature ofthe thermoforming material 414. The controller 132 determines, based onthe data from the temperature sensor 126, whether the temperature of thethermoforming material 414 meets a second temperature threshold. Similarto the first temperature threshold, the second temperature threshold maybe set by a dental aligner manufacturer/producer. The second temperaturethreshold may be static, or the second temperature threshold may bedynamic. The second temperature threshold may be, for instance, a rangeof temperatures. As one example, the second temperature threshold may be270° F.-350° F. The second temperature threshold may be a threshold usedfor advancing the thermoforming assembly 108 from the second heater 124to the forming station 112. In some embodiments, the second temperaturethreshold may be greater than 300° F., but no greater than 350° F.Hence, the controller 132 determines that the temperature of thethermoforming material 414 meets the second threshold when thetemperature is both (or either) greater than 300° F. and/or less than350° F.

When the controller 132 determines that the temperature of thethermoforming material 414 meets the second threshold, the controller132 controls the motor 120 to advance the thermoforming assembly 108from the second heater 124 to the forming station 112. When thecontroller 132 determines that the temperature of the thermoformingmaterial 414 does not meet the second threshold (e.g., is less than thelower limit of the second threshold), the controller 132 maintains thethermoforming assembly 108 at the second heater 124 until thetemperature of the thermoforming 414 meeting the second threshold.

In some embodiments, the controller 132 controls the first heater 122and second heater 124 based on data corresponding to the temperature ofthe thermoforming material 414 at the first heater 122 and/or thetemperature of the thermoforming material 414 at the second heater 124.For instance, the controller 132 monitors the temperature of thethermoforming material 414 at the first heater 122 and the thermoformingmaterial 414 at the second heater 124. In these embodiments, thecontroller 132 may increase the heat output from the first heater 122where the thermoforming material 414 at the first heater 122 lags behindthe first threshold and the thermoforming material 414 at the secondheater 124 approaches the second threshold. Additionally, the controller132 may decrease the heat output from the second heater 124 where thethermoforming material 414 at the first heater 122 lags behind the firstthreshold and the thermoforming material 414 at the second heater 124approaches the second threshold. In each of these embodiments, thecontroller 132 regulates the heat output of the first heater 122 and/orsecond heater 124 based on the data corresponding to the temperature ofthe thermoforming material 414 at the first heater 122 and/or thethermoforming material 414 at the second heater 124. Such embodimentsmay lessen the likelihood of bottlenecks and overheating thermoformingmaterial 414.

In some embodiments, the controller 132 controls the motor 120 toadvance the thermoforming assemblies 108 based on the temperature of thethermoforming material 414 at the first heater 122 and/or thethermoforming material 414 at the second heater 124. In theseembodiments, the controller 132 monitors data from the temperaturesensors 126 to determine whether the thermoforming material 414 at thefirst heater 122 meets the first threshold and the thermoformingmaterial 414 at the second heater 124 meets the second threshold. Thecontroller 132 advances the thermoforming assemblies 108 when boththermoforming materials 414 at the first heater 122 and second heater124 meet the respective thresholds. Where the temperature of onethermoforming material 414 meets one threshold but the temperature ofthe other thermoforming material 414 doesn't meet the other threshold,the controller 132 may control the corresponding heaters 122, 124 asdescribed above (e.g., increase one heat output for one heater 122and/or decrease heat output for the other heater 124).

When the thermoforming assembly 108 is located at the forming station,the controller 132 may generate a signal for the actuator 128. Thecontroller 132 may communicate the signal to the actuator 128 forcontrolling the actuator 128. The controller 132 may control theactuator 128 to press together the heated thermoforming material 414 andthe dental mold 406. The controller 132 controls the actuator 128 topress together the heated thermoforming material 414 and the dental mold408 for a duration of time (e.g., a number of seconds, minutes, etc.)for sufficiently thermoforming the thermoforming material 414 to thedental mold 408. The controller 132 may control the upper chamberstructure 134 and lifting device 136 to form a seal between the lowerperimeter of the upper chamber structure 134 and the dental mold nest404. The controller 132 controls the pressure system 138 to pressurize(e.g., via pressure system 138) the inner chamber formed by the upperchamber structure 134 and the dental mold nest 404. As the inner chamberis pressurized, the thermoforming material 414 forms around the dentalmold 406 (e.g., thereby thermoforming the thermoforming material 414 tothe dental mold 406). Following thermoforming of the thermoformingmaterial 414 to the dental mold 408, the controller 132 advances thethermoforming assembly 108 to subsequent stations for pushing thethermoforming assembly 108 with the dental aligners positioned thereon(or following the dental aligners being removed) from the firstmotorized belt 102 to the second motorized belt 114, and reloading(e.g., by an operator) additional dental molds 408 and thermoformingmaterial 414. Hence, the thermoforming assemblies 108 may be re-used forthermoforming additional dental aligners.

Referring to FIG. 10, a flowchart is depicted showing a method 1000 ofthermoforming dental aligners, according to an exemplary embodiment.

The method 1000 begins at operation 1005. At operation 1005, athermoforming assembly 108 is loaded with thermoforming material 414 anda dental mold 406. The thermoforming assembly 108 may be positioned on aloading belt, such as the second motorized belt 114. The samethermoforming assembly 108 may have previously contained thermoformingmaterial 414 and a different dental mold 406 and underwent a priorthermoforming operation. Hence, thermoforming assemblies 108 may bereused or recycled through the system 100 described above. In someembodiments, the thermoforming assembly 108 is loaded by an operator. Insome embodiments, the thermoforming assembly 108 is loaded automatically(e.g., by various articulated arms, robotic controls, etc.).

The thermoforming assembly 108 may generally be assembled while on theloading belt, such as the second motorized belt 114. An operator mayremove the retaining ring 420, place the thermoforming material 414 onthe thermoforming material nest 416, and re-attach the retaining ring420. Additionally, the operator may add the dental mold 406 to thedental mold nest 404.

At operation 1010, the loaded thermoforming assembly 108 is transferredfrom the loading belt to a thermoforming belt, such as the firstmotorized belt 102. In some embodiments, the transfer device 116transfers the thermoforming assembly 108 from the loading belt to thethermoforming belt. The controller 132 controls the transfer device 116to push the thermoforming assembly 108 between the cleats 104 on thethermoforming belt.

At operation 1015, the thermoforming assembly 108 (e.g., includingthermoforming material 414 and a dental mold 406) is positioned at afirst heater 122. The controller 132 controls a motor 120 for the firstmotorized belt 102 to move the thermoforming assembly 108 to the firstheater 122 (e.g., beneath the first heater 122). As the controller 132controls the motor 120 for the first motorized belt 102, eachthermoforming assembly on the first motorized belt 102 arecorrespondingly advanced. The controller 132 may control the motor 120in steps. For instance, the controller 132 may control the motor 120 tomove the first motorized belt 102 a predetermined distance sufficient tomove a thermoforming assembly 108 from one station to another station,and pause for a predetermined or controlled duration. Hence, eachthermoforming assembly 108 may advance within the system substantiallyin unison to prevent or eliminate bottlenecks.

At operation 1020, the first heater 122 heats the thermoforming material414. The first heater 122 heats the thermoforming material 414 locatedbeneath the first heater 122. In some embodiments, the controller 132controls the heat output of the first heater 122. For instance, thecontroller 132 may control the heat output of the first heater 122 basedon the temperature of the thermoforming material 414 at the first heater122 (e.g., lower the heat output of the first heater 122 as thetemperature of the thermoforming material 414 approaches the firsttemperature threshold when the temperature of the thermoforming material414 at the second heater 124 is not approaching the second temperaturethreshold).

At operation 1025, the controller 132 determines whether the temperatureof the thermoforming material 414 meets a first temperature threshold.The first temperature threshold may be a fixed temperature threshold.The fixed temperature threshold may depend on the type of material. Insome embodiments, the first temperature threshold may correspond to thesecond temperature threshold described below (e.g., in reference tooperation 1040). For instance, the first temperature threshold may behalf of (or approximately half of) the second temperature threshold.

In some embodiments, the controller 132 determines that the temperatureof the thermoforming material 414 meets the first temperature thresholdwhile the thermoforming assembly 108 including the thermoformingmaterial 414 and the dental mold 406 are located at the first heater122. The controller 132 determines whether the temperature of thethermoforming material 414 meets the first temperature threshold basedon the data from the temperature sensor 126 configured to detect atemperature of the thermoforming material 414 at the first heater 122 ofthe heating station 110. When the controller 132 determines thetemperature of the thermoforming material 414 does not meet the firsttemperature threshold, the controller 132 may maintain the position ofthe thermoforming assembly 108 at the first heater 122 (e.g., the firstheater 122 may continue to heat the thermoforming material 414). Hence,the method 1000 may return to operation 1020 until the temperature ofthe thermoforming material 414 meets the first temperature threshold.

In some embodiments, the first temperature threshold may be a range oftemperatures. For instance, the temperature of the thermoformingmaterial 414 may meet the first temperature threshold if the temperatureof the thermoforming material 414 falls within the range oftemperatures. The range of temperatures may be, for instance, 140°F.-200° F. In some embodiments, the range of temperatures (or firsttemperature threshold) may be a static threshold. In some embodiments,the range of temperatures (or first temperature threshold) may be adynamic threshold. The threshold may be set by the dental alignermanufacturer/producer. The threshold may correspond to the type ofthermoforming material 414. For instance, the threshold may be higherfor thicker and/or harder thermoforming materials 414 (e.g., having ahigher elastic modulus), and may be thinner and/or lower for softerthermoforming materials 414 (e.g., having a lower elastic modulus). Asanother example, the threshold may be different for thermoformingmaterial 414 having various chemical compositions which may contributeto different melting/softening points for proper thermoforming. Thecontroller 132 receives the temperature readings from the temperaturesensor(s) 126. The controller 132 compares the temperature to the firsttemperature threshold to determine whether the temperature of thethermoforming material 414 meets the first temperature threshold.

At operation 1030, the controller 132 advances the thermoformingassembly 108 from the first heater 122 to the second heater 124. In someembodiment, the controller 132 controls a motor 120 of the firstmotorized belt 102 upon which the thermoforming assembly 108 is locatedto advance the thermoforming assembly 108 from the first heater 122 tothe second heater 124 at the heating station 110. The controller 132communicates a signal to the motor 120 which causes the motor to rotatethe first motorized belt 102 (e.g., in the direction A). The motor 120causes the first motorized belt 102 to advance the thermoformingassembly 108 to the second heater 124. The controller 132 advances thethermoforming assembly 108 from the first heater 122 to the secondheater 124 responsive to the controller 132 determining that thetemperature of the thermoforming material 414 meets the firsttemperature threshold.

At operation 1035, the thermoforming material 414 is heated by thesecond heater 124. The first heater 124 heats the thermoforming material414 located beneath the second heater 124. In some embodiments, thecontroller 132 controls the heat output of the second heater 124. Forinstance, the controller 132 may control the heat output of the secondheater 124 based on the temperature of the thermoforming material 414 atthe second heater 124 (e.g., increase the output of the second heater124 where the temperature of the thermoforming material 414 is notsufficiently approaching the second temperature threshold when thetemperature of the thermoforming material 414 at the first heater 122 isapproaching the first temperature threshold).

At operation 1040, the controller 132 determines whether the temperatureof the thermoforming material 414 meets a second temperature threshold.In some embodiments, the controller 132 determines that the temperatureof the thermoforming material 414 meets the second temperature thresholdwhile the thermoforming assembly 108 is located at the second heater124. The controller 132 determines the temperature of the thermoformingmaterial 414 meets the second temperature threshold based on data fromthe temperature sensor 126. Accordingly, operation 1020 may be similarto operation 1010. When the controller 132 determines the temperature ofthe thermoforming material 414 does not meet the second temperaturethreshold, the controller 132 maintains the position of thethermoforming assembly 108 at the second heater 124. Hence, the method1000 may return to operation 1035 until the temperature of thethermoforming material 414 meets the second temperature threshold.

In some embodiments, the second temperature threshold may be a range oftemperatures. For instance, the temperature of the thermoformingmaterial 414 may meet the second temperature threshold if thetemperature of the thermoforming material 414 falls within the range oftemperatures. The range of temperatures may be, for instance, 270°F.-350° F. In some embodiments, the range of temperatures (or secondtemperature threshold) may be a static threshold. In some embodiments,the range of temperatures (or second temperature threshold) may be adynamic threshold. The threshold may be set by the dental alignermanufacturer/producer. In some embodiments, the threshold may correspondto the type of thermoforming material 414. For instance, the thresholdmay be higher for harder/thicker thermoforming materials 414, and may belower for softer/thinner thermoforming materials 414. The controller 132receives the temperature readings from the temperature sensor(s) 126.The controller 132 compares the temperature to the second temperaturethreshold to determine whether the temperature of the thermoformingmaterial 414 meets the second temperature threshold.

At operation 1045, the controller 132 advances the thermoformingassembly 108 from the second heater 124 to the forming station 112. Insome embodiments, the controller 132 controls the motor 120 of the firstmotorized belt 102 to advance the thermoforming assembly 108 from thesecond heater 124 to the forming station 112. The controller 132communicates a signal to the motor 120 which causes the motor to rotatethe first motorized belt 102 (e.g., in the direction A). The motor 120causes the first motorized belt 102 to advance the thermoformingassembly 108 to the forming station. The controller 132 advances thethermoforming assembly 108 from the second heater 124 to the formingstation 112 responsive to the controller 132 determining that thetemperature of the thermoforming material 414 meets the secondtemperature threshold.

At operation 1050, an actuator 128 presses together the heatedthermoforming material 414 and the dental mold 406. In some embodiments,the controller 132 controls the actuator 128 and the pressure system 138at the forming station 112 to press together the heated thermoformingmaterial 414 and the dental mold 406 to thermoform the thermoformingmaterial 414 to the dental mold 406. In some embodiments, the actuator128 is controlled mechanically, using pneumatic pressure, using avacuum, using hydraulics, or any combination thereof. In someembodiments, the pressure system 138 controls movement of the actuator128. The controller 132 controls the actuator 128 responsive todetermining that the temperature of the thermoforming material 414 meetsthe third temperature threshold (e.g., a temperature for thermoformingthe thermoforming material 414, a temperature substantially the same asthe second temperature threshold, a temperature less than the secondtemperature threshold) and the thermoforming assembly 108 is positionedat the forming station 112. Hence, the controller 128 controls theactuator 128 when the thermoforming assembly 108 is suitably located atthe forming station 112.

The actuator 128 includes an upper chamber structure 134 and a liftingdevice 136. The controller 132 controls the lifting device 136 to liftthe dental mold nest 404 with the dental mold 406 towards thethermoforming material 414. The controller 132 controls the upperchamber structure 134 to move downwardly towards the thermoformingmaterial 414. The upper chamber structure 134 is aligned with the dentalmold nest 404 such that the upper chamber structure 134 and dental moldnest 404 sandwich the thermoforming material 414. The thermoformingmaterial 414 acts as a seal. The controller 132 controls the pressuresystem 138 to depressurize the inner chamber formed by the upper chamberstructure 134 and the dental mold nest 404. In another embodiment,pressurized air may be introduced through the upper chamber structure134 to pressurize the air above the thermoforming material 414, causingthe thermoforming material 414 to thermoform to the dental mold 406. Itwill be appreciated that either or both negative air pressure (e.g.,applied via a vacuum from the bottom of the chamber), and positive airpressure (e.g., applied from the top of the chamber), can be applied tothe chamber to cause the thermoforming material 414 to mold onto thedental mold 406, thereby resulting in a thermoformed dental aligner. Thedental mold 406 and thermoforming material 414 thus have complementarysurface contours (e.g., the thermoforming material 414 may become anegative impression of the dental mold 406).

In some embodiments, the method 1000 further includes transferring thethermoforming assembly 108 including the thermoforming material 414 anddental mold 406 from the thermoforming belt (e.g., the second motorizedbelt 114) to the loading belt (e.g., the first motorized belt 102),where the thermoforming assemblies 108 may be loaded (e.g., by anoperator), and then transferred back on the first motorized belt 102 forthermoforming. When unloading a thermoforming assembly 108, an operatormay remove the dental aligner and dental mold 306 (which may be stucktogether) and then reload the thermoforming assembly 108 by adding a newdental mold 306 and new thermoforming material 414, before the reloadedthermoforming assembly 108 is transferred back to onto the firstmotorized belt 102 for thermoforming.

In one or more embodiments, the method 1000 described above may be usedfor creating a set of aligners where each aligner corresponds to thesame dental mold 406 but has a different thickness and/or hardness(e.g., as indicated by an elastic modulus). In some embodiments, the setof aligners may be created by separate systems 100. In some embodiments,the set of aligners may be created by the same system 100. Each of theseembodiments will be described in greater detail below.

As described above, the set of aligners may have different hardnessand/or different thicknesses. For instance, a set of aligners maycorrespond to two or more aligners constructed of different types ofthermoforming material 414. The aligners may be constructed of a softerand/or thinner thermoforming material 414, a thermoforming material 414of an intermediate hardness and/or thickness, and a harder and/orthicker thermoforming material 414 (relative to one another). In someembodiments, the aligners may be constructed of different materialshaving material properties other than or in addition to a hardness orthickness of the material, such as a chemistry of the material, a shapeof the material, a color of the material, or other unique materialproperty. Each of the thermoforming materials 414 have correspondingcharacteristics, such as thermoforming temperature, which are used bythe system 100 for creating the aligners. The soft/thin aligner, theintermediate hardness/thickness aligner, and the hard/thick aligner areeach used in stages for repositioning the user's teeth. For example, auser can be instructed to first wear a soft and/or thin aligner of theset for a first time period, to then wear the intermediate hardnessand/or thickness aligner of the set for a second time period, and thenwear the hard and/or thick aligner of the set for a third time period.The time periods may be the same (e.g., one week, two weeks, threeweeks) or different. For example, any of the softer and/or thinner,intermediate hardness and/or thickness, and hard and/or thick alignerscan be worn for either a shortest or longest time period (e.g., thesoft/thin aligner is worn for a shorter duration than the aligner ofintermediate hardness/thickness and the hard/thick aligner). Thesoft/thin aligner can provide a lowest amount of force to the user'steeth, the intermediate hardness/thickness aligner can provide anintermediate amount of force to the user's teeth, and the hard/thickaligner can provide a greatest amount of force to the user's teeth. Assuch, the force level or pressure level exerted by the aligners on theuser's teeth can vary according to a characteristic of the material thatthe aligner is made from.

The aligners may be generated using the system 100 described above. Insome embodiments, various components of the system 100, such as theheaters 122,124 and pressure system 138, may be adjusted based on thetype of the thermoforming material 144. For instance, the temperaturethresholds may be modified based on the type of thermoforming material414. The temperature thresholds may be increased for harder/thickerthermoforming materials 414, and decreased for softer/thinnerthermoforming materials 414. Hence, the duration at which thethermoforming material 414 is heated by a respective heater (or the heatoutput of a respective heater) may be changed based on the type of thethermoforming material. In some embodiments, the pressure inside theinner chamber formed by the upper chamber structure 134 and the dentalmold nest 404 may be adjusted based on the type of thermoformingmaterial 414. For instance, the pressure may be increased inside theinner chamber for harder/thicker thermoforming materials 414, and may bedecreased inside the inner chamber for softer/thinner thermoformingmaterials 414, or vice versa. In each of these embodiments, thecharacteristics of the components of the system 100 may correspond tothe type of thermoforming material 414.

In some embodiments, one system 100 may be used for producing a set ofaligners. For instance, the components within a single system 100, suchas the heaters 122, 124, the pressure system 138, etc. are adjustedbased on the type of thermoforming material 414. The controller 132 mayreceive an input (e.g., from an operator) corresponding to the type ofthermoforming material 414 (e.g., identifying the specific material, thehardness, the thickness, a category, etc.) or the controller 132 mayreceive an input from an indicator on the mold 406. The controller 132selects parameters, including heater temperature, pressure, etc. basedon the type of thermoforming material 414. In this regard, thecontroller 132 dynamically adjusts components within the system 100 inaccordance with the type of thermoforming material 414. The operator mayassemble one thermoforming assembly 108 using a first thermoformingmaterial and a dental mold, initiate the thermoforming process on thesystem 100, remove the first thermoforming material thermoformed to thedental mold, and repeat the thermoforming process using a second (andsubsequent) thermoforming material with the same dental mold and thesame system 100.

In some embodiments, a plurality of systems 100 may be used forproducing a set of aligners. For instance, each component within arespective system 100 may be configured for thermoforming a particulartype of thermoforming material 414. The heaters 122, 124 output a presetheat output, the pressure system 138 depressurizes the inner chamber toa preset pressure, etc., in accordance with a particular type ofthermoforming material 414. An operator may assemble one thermoformingassembly 108 using a first thermoforming material and a dental mold andinitiate the thermoforming process on a first system 100. The operatormay remove the thermoformed first thermoforming material, reassemble athermoforming assembly with a second thermoforming material and the samedental mold, and initiate the thermoforming process on a second system100.

As utilized herein, the terms “approximately,” “about,” “substantially”,and similar terms are intended to have a broad meaning in harmony withthe common and accepted usage by those of ordinary skill in the art towhich the subject matter of this disclosure pertains. It should beunderstood by those of skill in the art who review this disclosure thatthese terms are intended to allow a description of certain featuresdescribed and claimed without restricting the scope of these features toany precise numerical ranges provided. Accordingly, these terms shouldbe interpreted as indicating that insubstantial or inconsequentialmodifications or alterations of the subject matter described and claimedare considered to be within the scope of the disclosure as recited inthe appended claims.

It should be noted that the term “exemplary” and variations thereof, asused herein to describe various embodiments, are intended to indicatethat such embodiments are possible examples, representations, orillustrations of possible embodiments (and such terms are not intendedto connote that such embodiments are necessarily extraordinary orsuperlative examples).

The term “coupled” and variations thereof, as used herein, means thejoining of two members directly or indirectly to one another. Suchjoining may be stationary (e.g., permanent or fixed) or moveable (e.g.,removable or releasable). Such joining may be achieved with the twomembers coupled directly to each other, with the two members coupled toeach other using a separate intervening member and any additionalintermediate members coupled with one another, or with the two memberscoupled to each other using an intervening member that is integrallyformed as a single unitary body with one of the two members. If“coupled” or variations thereof are modified by an additional term(e.g., directly coupled), the generic definition of “coupled” providedabove is modified by the plain language meaning of the additional term(e.g., “directly coupled” means the joining of two members without anyseparate intervening member), resulting in a narrower definition thanthe generic definition of “coupled” provided above. Such coupling may bemechanical, electrical, or fluidic.

The term “or,” as used herein, is used in its inclusive sense (and notin its exclusive sense) so that when used to connect a list of elements,the term “or” means one, some, or all of the elements in the list.Conjunctive language such as the phrase “at least one of X, Y, and Z,”unless specifically stated otherwise, is understood to convey that anelement may be either X, Y, Z; X and Y; X and Z; Y and Z; or X, Y, and Z(i.e., any combination of X, Y, and Z). Thus, such conjunctive languageis not generally intended to imply that certain embodiments require atleast one of X, at least one of Y, and at least one of Z to each bepresent, unless otherwise indicated.

References herein to the positions of elements (e.g., “top,” “bottom,”“above,” “below”) are merely used to describe the orientation of variouselements in the Figures. It should be noted that the orientation ofvarious elements may differ according to other exemplary embodiments,and that such variations are intended to be encompassed by the presentdisclosure.

The hardware and data processing components used to implement thevarious processes, operations, illustrative logics, logical blocks,modules and circuits described in connection with the embodimentsdisclosed herein may be implemented or performed with a general purposesingle- or multi-chip processor, a digital signal processor (DSP), anapplication specific integrated circuit (ASIC), a field programmablegate array (FPGA), or other programmable logic device, discrete gate ortransistor logic, discrete hardware components, or any combinationthereof designed to perform the functions described herein. A generalpurpose processor may be a microprocessor, or, any conventionalprocessor, controller, microcontroller, or state machine. A processoralso may be implemented as a combination of computing devices, such as acombination of a DSP and a microprocessor, a plurality ofmicroprocessors, one or more microprocessors in conjunction with a DSPcore, or any other such configuration. In some embodiments, particularprocesses and methods may be performed by circuitry that is specific toa given function. The memory (e.g., memory, memory unit, storage device)may include one or more devices (e.g., RAM, ROM, Flash memory, hard diskstorage) for storing data and/or computer code for completing orfacilitating the various processes, layers and modules described in thepresent disclosure. The memory may be or include volatile memory ornon-volatile memory, and may include database components, object codecomponents, script components, or any other type of informationstructure for supporting the various activities and informationstructures described in the present disclosure. According to anexemplary embodiment, the memory is communicably connected to theprocessor via a processing circuit and includes computer code forexecuting (e.g., by the processing circuit or the processor) the one ormore processes described herein.

The present disclosure contemplates methods, systems and programproducts on any machine-readable media for accomplishing variousoperations. The embodiments of the present disclosure may be implementedusing existing computer processors, or by a special purpose computerprocessor for an appropriate system, incorporated for this or anotherpurpose, or by a hardwired system. Embodiments within the scope of thepresent disclosure include program products comprising machine-readablemedia for carrying or having machine-executable instructions or datastructures stored thereon. Such machine-readable media can be anyavailable media that can be accessed by a general purpose or specialpurpose computer or other machine with a processor. By way of example,such machine-readable media can comprise RAM, ROM, EPROM, EEPROM, orother optical disk storage, magnetic disk storage or other magneticstorage devices, or any other medium which can be used to carry or storedesired program code in the form of machine-executable instructions ordata structures and which can be accessed by a general purpose orspecial purpose computer or other machine with a processor. Combinationsof the above are also included within the scope of machine-readablemedia. Machine-executable instructions include, for example,instructions and data which cause a general purpose computer, specialpurpose computer, or special purpose processing machines to perform acertain function or group of functions.

Although the figures and description may illustrate a specific order ofmethod steps, the order of such steps may differ from what is depictedand described, unless specified differently above. Also, two or moresteps may be performed concurrently or with partial concurrence, unlessspecified differently above. Such variation may depend, for example, onthe software and hardware systems chosen and on designer choice. Allsuch variations are within the scope of the disclosure. Likewise,software implementations of the described methods could be accomplishedwith standard programming techniques with rule-based logic and otherlogic to accomplish the various connection steps, processing steps,comparison steps, and decision steps. It is important to note that theconstruction and arrangement of the systems and methods of thermoformingdental aligners as shown in the various exemplary embodiments isillustrative only. Additionally, any element disclosed in one embodimentmay be incorporated or utilized with any other embodiment disclosedherein. It should be appreciated that other elements of the variousembodiments may be incorporated or utilized with any of the otherembodiments disclosed herein.

What is claimed is:
 1. A system comprising: a forming system configuredto receive a dental assembly including a dental mold and a material thathas been heated, to form a chamber encompassing the dental mold and afirst portion of the material by interfacing with a second portion ofthe material, and to cause at least part of the first portion of thematerial to form over the dental mold.
 2. The system of claim 1, whereinthe chamber is airtight or substantially airtight.
 3. The system ofclaim 1, wherein the chamber is formed by contacting the second portionof the material between an upper component of the forming system and acomponent of the dental assembly.
 4. The system of claim 1, wherein theforming system comprises an actuator configured to cause the dental moldand the material to engage with one another.
 5. The system of claim 4,wherein the actuator is configured to cause the dental mold and thematerial to engage by at least one of moving the dental mold towards thematerial, moving the material towards the dental mold, or applying avacuum to the chamber.
 6. The system of claim 1, further comprising: aheating system configured to heat the material of the dental assemblyprior to the dental assembly being received by the forming system. 7.The system of claim 6, further comprising: a controller configured tocontrol the heating system to heat the material above a temperaturethreshold or within a temperature range and to cause movement of thedental assembly from the heating system to the forming system.
 8. Asystem comprising: a dental assembly including a dental mold and amaterial that has been heated, the dental assembly configured to supportthe material; and a forming system configured to receive the dentalassembly, to form a chamber encompassing the dental mold and a firstportion of the material by interfacing with a second portion of thematerial, and to cause at least a dental aligner portion of the firstportion of the material to form over the dental mold in the shape of adental aligner, wherein the second portion of the material is anon-dental aligner portion of the material, and wherein the chamber isformed by contacting the second portion of the material between an uppercomponent of the forming system and a component of the dental assembly.9. The system of claim 8, wherein the chamber is airtight orsubstantially airtight.
 10. The system of claim 8, wherein the formingsystem is configured to apply vacuum suction to the chamber to cause thematerial to form over the dental mold.
 11. The system of claim 8,wherein the forming system is configured to apply pressure to thechamber to cause the heated material to compress onto the dental mold.12. The system of claim 8, wherein the forming system includes anactuator configured to cause the dental mold and the material to engage.13. The system of claim 12, wherein the actuator is configured to causethe dental mold and the material to engage by at least one of moving thedental mold towards the material, moving the material towards the dentalmold, or applying a vacuum to the chamber.
 14. The system of claim 8,further comprising: a heating system configured to heat the material ofthe dental assembly prior to the dental assembly being received by theforming system.
 15. The system of claim 14, further comprising: aconveyor system configured to move the dental assembly from the heatingsystem to the forming system.
 16. The system of claim 15, furthercomprising: a controller configured to control the heating system toheat the material above a temperature threshold or within a temperaturerange and to cause movement of the dental assembly from the heatingsystem to the forming system.
 17. A forming system for manufacturingdental aligners, the forming system comprising: an upper component; andan actuator configured to cause formation of a chamber encompassing adental mold and a first portion of a material that has been heated bycausing a second portion of the material to interface with the uppercomponent, wherein the actuator is configured to cause formation of thechamber by moving the dental mold and the material toward the uppercomponent to press the second portion of the material to onto the uppercomponent, wherein the second portion of the material is a non-dentalaligner portion of the material.
 18. The forming system of claim 17,wherein the actuator is configured to cause formation of the chamber byat least one of moving the dental mold towards the material, moving thematerial towards the dental mold, or applying a vacuum to the chamber.19. The forming system of claim 17, further comprising: a vacuum systemconfigured to apply vacuum suction to the chamber to cause the materialto form over the dental mold.
 20. The forming system of claim 17,wherein the material is a polymeric material.